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Is there a library function that performs binary search on a list/tuple and return the position of the item if found and 'False' (-1, None, etc.) if not?

I found the functions bisect_left/right in the bisect module, but they still return a position even if the item is not in the list. That's perfectly fine for their intended usage, but I just want to know if an item is in the list or not (don't want to insert anything).

I thought of using bisect_left and then checking if the item at that position is equal to what I'm searching, but that seems cumbersome (and I also need to do bounds checking if the number can be larger than the largest number in my list). If there is a nicer method I'd like to know about it.

Edit To clarify what I need this for: I'm aware that a dictionary would be very well suited for this, but I'm trying to keep the memory consumption as low as possible. My intended usage would be a sort of double-way look-up table. I have in the table a list of values and I need to be able to access the values based on their index. And also I want to be able to find the index of a particular value or None if the value is not in the list.

Using a dictionary for this would be the fastest way, but would (approximately) double the memory requirements.

I was asking this question thinking that I may have overlooked something in the Python libraries. It seems I'll have to write my own code, as Moe suggested.

share|improve this question
What is it you're trying to accomplish? If the values are unique, consider using a set and "if value in set: something". – Kirk Strauser Oct 17 '08 at 15:03
For what it's worth, "-1" is considered true; "0" would be false. – Glyph Oct 18 '08 at 5:12
I mentioned -1 because a function that returns the index of the searched item in the array can return 0 already so -1 is returned if the item is not found (similar to substring search). – rslite Oct 18 '08 at 11:00
If you use numpy, np.searchsorted is useful. docs.scipy.org/doc/numpy/reference/generated/… – Roman Shapovalov Apr 25 '13 at 11:56

16 Answers 16

up vote 166 down vote accepted
from bisect import bisect_left

def binary_search(a, x, lo=0, hi=None):   # can't use a to specify default for hi
    hi = hi if hi is not None else len(a) # hi defaults to len(a)   
    pos = bisect_left(a,x,lo,hi)          # find insertion position
    return (pos if pos != hi and a[pos] == x else -1) # don't walk off the end
share|improve this answer
This is the only correct answer - I am quite baffled. Everyone's presenting new code - code which might or might not be correct (particular for edge cases and special cases). But you know for sure that the library code is correct - because it's been around for over a decade and used countless times. And what's his objection to it? That he has to add two lines of test code! – Tom Swirly Oct 24 '12 at 20:43
Oh, and you can replace the second line by hi = hi or len(a) - much simpler. – Tom Swirly Oct 24 '12 at 20:44
@TomSwirly, I haven't thought it through but are you sure about that simplification? hi could turn out to be zero. – Dave Abrahams Nov 17 '12 at 2:50
My original thought was that hi=0 made no sense, but now I don't think it's right and looking at it now, it would be unexpected to pass hi=0 and then get a search of the whole array, so I think you're right that I'm wrong about the simplification. – Tom Swirly Nov 18 '12 at 3:24
@volcano So does binsearch in general. – cubuspl42 Jul 5 '14 at 20:13

Why not look at the code for bisect_left/right and adapt it to suit your purpose.

like this:

def binary_search(a, x, lo=0, hi=None):
    if hi is None:
        hi = len(a)
    while lo < hi:
        mid = (lo+hi)//2
        midval = a[mid]
        if midval < x:
            lo = mid+1
        elif midval > x: 
            hi = mid
            return mid
    return -1
share|improve this answer
I originally +1'ed this, but now I've come to the conclusion this isn't a good thing. If this answer is followed, it'll cause a lot of code duplication, and as we all know, it's really simple to f*ck up binary search. – abyx Oct 30 '09 at 16:23
shouldn't it be hi = mid - 1 in the elif? – Paweł Prażak Feb 5 '11 at 18:50
@Paweł: they are two equivalent variants, depending on whether the upper bound is inclusive or exclusive. you can change hi = mid to hi = mid-1 and hi = len(a) to hi = len(a)-1 and while lo < hi: to while lo <= hi, and it would be equivalently correct – user102008 Apr 6 '11 at 10:42
why not do something like: def binary_search(a, x, lo = 0, hi = None): i = bisect(a, x, lo, hi) return i if a[i] == x else -1 sorry for the formatting - not sure how to do this properly in the comment arrea – Vitali Feb 29 '12 at 1:44
You should use bisect.bisect_left() rather than this. – alastair Nov 7 '12 at 11:26

This is a little off-topic (since Moe's answer seems complete to the OP's question), but it might be worth looking at the complexity for your whole procedure from end to end. If you're storing thing in a sorted lists (which is where a binary search would help), and then just checking for existence, you're incurring (worst-case, unless specified):

Sorted Lists

  • O( n log n) to initially create the list (if it's unsorted data. O(n), if it's sorted )
  • O( log n) lookups (this is the binary search part)
  • O( n ) insert / delete (might be O(1) or O(log n) average case, depending on your pattern)

Whereas with a set(), you're incurring

  • O(n) to create
  • O(1) lookup
  • O(1) insert / delete

The thing a sorted list really gets you are "next", "previous", and "ranges" (including inserting or deleting ranges), which are O(1) or O(|range|), given a starting index. If you aren't using those sorts of operations often, then storing as sets, and sorting for display might be a better deal overall. set() incurs very little additional overhead in python.

share|improve this answer
There is one other thing a sorted list gets you. O(n) ordered traversal. With a set that's O(n log n) and you end up having to copy references to the data into a list. – Omnifarious Mar 30 '10 at 19:47
True enough! Thank you for expanding on what I meant by range search. Fwiw, a full traversal is the same a range query between min,max, which is O(k) where k = n :) – Gregg Lind Mar 31 '10 at 12:35

Simplest is to use bisect and check one position back to see if the item is there:

def binary_search(a,x,lo=0,hi=-1):
    i = bisect(a,x,lo,hi)
    if i == 0:
        return -1
    elif a[i-1] == x:
        return i-1
        return -1
share|improve this answer
Nice, but the code barfs if you do not pass in the 'hi' value. I'd write it like this: "def binary_search(a,x,lo=0,hi=None): from bisect import bisect i = bisect(a,x,lo,hi or len(a)) return (i-1 if a[i-1] == x else -1) " and test it like this: " for i in range(1, 20): a = list(range(i)) for aa in a: j = binary_search(a, aa) if j != aa: print i, aa, j" – hughdbrown Aug 6 '09 at 20:02

It might be worth mentioning that the bisect docs now provide searching examples: http://docs.python.org/library/bisect.html#searching-sorted-lists

(Raising ValueError instead of returning -1 or None is more pythonic – list.index() does it, for example. But of course you can adapt the examples to your needs.)

share|improve this answer

I agree that @DaveAbrahams's answer using the bisect module is the correct approach. He did not mention one important detail in his answer.

From the docs bisect.bisect_left(a, x, lo=0, hi=len(a))

The bisection module does not require the search array to be precomputed ahead of time. You can just present the endpoints to the bisect.bisect_left instead of it using the defaults of 0 and len(a).

Even more important for my use, looking for a value X such that the error of a given function is minimized. To do that, I needed a way to have the bisect_left's algorithm call my computation instead. This is really simple.

Just provide an object that defines __getitem__ as a

For example, we could use the bisect algorithm to find a square root with arbitrary precision!

import bisect

class sqrt_array(object):
    def __init__(self, digits):
        self.precision = float(10**(digits))
    def __getitem__(self, key):
        return (key/self.precision)**2.0

sa = sqrt_array(4)

# "search" in the range of 0 to 10 with a "precision" of 0.0001
index = bisect.bisect_left(sa, 7, 0, 10*10**4)
print 7**0.5
print index/(10**4.0)
share|improve this answer
This is not clean. Use scipy.optimize for this. – Neil G Oct 30 '15 at 9:51

This is right from the manual:


8.5.1. Searching Sorted Lists

The above bisect() functions are useful for finding insertion points but can be tricky or awkward to use for common searching tasks. The following five functions show how to transform them into the standard lookups for sorted lists:

def index(a, x):
    'Locate the leftmost value exactly equal to x'
    i = bisect_left(a, x)
    if i != len(a) and a[i] == x:
        return i
    raise ValueError

So with the slight modification your code should be:

def index(a, x):
    'Locate the leftmost value exactly equal to x'
    i = bisect_left(a, x)
    if i != len(a) and a[i] == x:
        return i
    return -1
share|improve this answer

If you just want to see if it's present, try turning the list into a dict:

# Generate a list
l = [n*n for n in range(1000)]

# Convert to dict - doesn't matter what you map values to
d = dict((x, 1) for x in l)

count = 0
for n in range(1000000):
    # Compare with "if n in l"
    if n in d:
        count += 1

On my machine, "if n in l" took 37 seconds, while "if n in d" took 0.4 seconds.

share|improve this answer
set(l) could do the job. – J.F. Sebastian Oct 17 '08 at 15:06
That's not always a good option for a couple of reasons: 1) dicts/sets take up more memory. 2) if he doesn't have much in the list, a binary search may be faster. 3) converting the list to a dict is an O(n) operation while a binary search is O(log n). – Jason Baker Oct 17 '08 at 15:10
As an FYI, the "set" overhead in python compared to python lists, is very very low. And they are extremely fast for lookups. Where binary search really excels is for looking up ranges. – Gregg Lind Oct 17 '08 at 16:43
Converting the list may be O(n) but sorting the data in the list, which you'd have to do before binary searching it, is worse. Where's the data coming from, you can probably insert it into a dictionary as you go. I agree that the memory may be an issue. – Mark Baker Oct 20 '08 at 15:56

While there's no explicit binary search algorithm in Python, there is a module - bisect - designed to find the insertion point for an element in a sorted list using a binary search. This can be "tricked" into performing a binary search. The biggest advantage of this is the same advantage most library code has - it's high-performing, well-tested and just works (binary searches in particular can be quite difficult to implement successfully - particularly if edge cases aren't carefully considered).

Basic Types

For basic types like Strings or ints it's pretty easy - all you need is the bisect module and a sorted list:

>>> import bisect
>>> names = ['bender', 'fry', 'leela', 'nibbler', 'zoidberg']
>>> bisect.bisect_left(names, 'fry')
>>> keyword = 'fry'
>>> x = bisect.bisect_left(names, keyword)
>>> names[x] == keyword
>>> keyword = 'arnie'
>>> x = bisect.bisect_left(names, keyword)
>>> names[x] == keyword

You can also use this to find duplicates:

>>> names = ['bender', 'fry', 'fry', 'fry', 'leela', 'nibbler', 'zoidberg']
>>> keyword = 'fry'
>>> leftIndex = bisect.bisect_left(names, keyword)
>>> rightIndex = bisect.bisect_right(names, keyword)
>>> names[leftIndex:rightIndex]
['fry', 'fry', 'fry']

Obviously you could just return the index rather than the value at that index if desired.


For custom types or objects, things are a little bit trickier: you have to make sure to implement rich comparison methods to get bisect to compare correctly.

>>> import bisect
>>> class Tag(object):  # a simple wrapper around strings
...     def __init__(self, tag):
...         self.tag = tag
...     def __lt__(self, other):
...         return self.tag < other.tag
...     def __gt__(self, other):
...         return self.tag > other.tag
>>> tags = [Tag('bender'), Tag('fry'), Tag('leela'), Tag('nibbler'), Tag('zoidbe
>>> key = Tag('fry')
>>> leftIndex = bisect.bisect_left(tags, key)
>>> rightIndex = bisect.bisect_right(tags, key)
>>> print([tag.tag for tag in tags[leftIndex:rightIndex]])

This should work in at least Python 2.7 -> 3.3

share|improve this answer

Using a dict wouldn't like double your memory usage unless the objects you're storing are really tiny, since the values are only pointers to the actual objects:

>>> a = 'foo'
>>> b = [a]
>>> c = [a]
>>> b[0] is c[0]

In that example, 'foo' is only stored once. Does that make a difference for you? And exactly how many items are we talking about anyway?

share|improve this answer
It's about numbers and lots of them :) I'd like to use an array almost as big as the computer memory. I know the base of my problem could be wrong, but I was curious about the lack of a binary search method. – rslite Oct 18 '08 at 11:07
You can't have a key object small enough to qualify as "really tiny" here. An object would have a minimum cost of 3 words (type, refcount, payload), while a list adds 1 word, a set adds 1 word, and a dict adds 2 words. All three (list/set/dict) preallocate space in some fashion as well, which is another multiplier, but still not enough to matter. – Rhamphoryncus Nov 9 '09 at 20:37

This code works with integer lists in a recursive way. Looks for the simplest case scenario, which is: list length less than 2. It means the answer is already there and a test is performed to check for the correct answer. If not, a middle value is set and tested to be the correct, if not bisection is performed by calling again the function, but setting middle value as the upper or lower limit, by shifting it to the left or right

def binary_search(intList, intValue, lowValue, highValue):
    if(highValue - lowValue) < 2:
        return intList[lowValue] == intValue or intList[highValue] == intValue
    middleValue = lowValue + ((highValue - lowValue)/2)
    if intList[middleValue] == intValue:
        return True
    if intList[middleValue] > intValue:
        return binary_search(intList, intValue, lowValue, middleValue - 1)
   return binary_search(intList, intValue, middleValue + 1, highValue)
share|improve this answer

Dave Abrahams' solution is good. Although I have would have done it minimalistic:

def binary_search(L, x):
    i = bisect.bisect_left(L, x)
    if i == len(L) or L[i] != x:
        return -1
    return i
share|improve this answer

Check out the examples on Wikipedia http://en.wikipedia.org/wiki/Binary_search_algorithm

def binary_search(a, key, imin=0, imax=None):
    if imax is None:
        # if max amount not set, get the total
        imax = len(a) - 1

    while imin <= imax:
        # calculate the midpoint
        mid = (imin + imax)//2
        midval = a[mid]

        # determine which subarray to search
        if midval < key:
            # change min index to search upper subarray
            imin = mid + 1
        elif midval > key:
            # change max index to search lower subarray
            imax = mid - 1
            # return index number 
            return mid
    raise ValueError
share|improve this answer

This one is:

  • not recursive (which makes it more memory-efficient than most recursive approaches)
  • actually working
  • fast since it runs without any unnecessary if's and conditions
  • based on a mathematical assertion that the floor of (low + high)/2 is always smaller than high where low is the lower limit and high is the upper limit.
  • tested :D

def binsearch(t, key, low = 0, high = len(t) - 1):
    # bisecting the range
    while low < high:
        mid = (low + high)//2
        if t[mid] < key:
            low = mid + 1
            high = mid
    # at this point 'low' should point at the place
    # where the value of 'key' is possibly stored.
    return low if t[low] == key else -1
share|improve this answer
Only used if set your position as global
position #set global 

def bst(array,taget): # just pass the array and target
        global position
        low = 0
        high = len(array)
    while low <= high:
        mid = (lo+hi)//2
        if a[mid] == target:
            position = mid
            return -1
        elif a[mid] < target: 
            high = mid+1
            low = mid-1
    return -1

I guess this is much better and effective. please correct me :) . Thank you

share|improve this answer
  • s is a list.
  • binary(s, 0, len(s) - 1, find) is the initial call.
  • Function returns an index of the queried item. If there is no such item it returns -1.

    def binary(s,p,q,find):
        if find==s[(p+q)/2]:
            return (p+q)/2
        elif p==q-1 or p==q:
            if find==s[q]:
                return q
                return -1
        elif find < s[(p+q)/2]:
            return binary(s,p,(p+q)/2,find)
        elif find > s[(p+q)/2]:
            return binary(s,(p+q)/2+1,q,find)
share|improve this answer

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